Not Applicable
The various aspects and embodiments described herein relate to a mechanism for a sliding door.
A sliding door may have a track on which the door slides to traverse the door between an opened and closed position. The rolling friction between the track and the door may be excessive due to doors that are very heavy. In this instance, it may be difficult to traverse the door between the closed and opened positions. Moreover, the very heavy door may cause other failures because of the repetitive and cyclical opening and closing of the door over a long period of time.
Accordingly, there is a need in the art for improved mechanism for a sliding door.
This application is related to U.S. patent application Ser. No. 16/392,347, filed on Apr. 23, 2019, U.S. patent application Ser. No. 16/032,455, filed on Jul. 11, 2018, U.S. Prov. Pat. App. No. 62/525,118, filed on Jun. 26, 2017, and U.S. Prov. Pat. App. No. 62/427,024, filed on Nov. 28, 2016, the entire contents of which are expressly incorporated by reference herein.
A track that extends across the door opening and a door that magnetically engages the track are disclosed herein. The door does not physically contact the track and if the door does physically contact the track, only a small fraction of the weight of the door is transferred to the track. In this regard, the lack of physical contact between the track and the door allows the door to be traversed smoothly between the opened and closed positions and the rolling friction between the door and the track is substantially eliminated or minimized. The track and the door may have magnets that repel each other and lift the door away from the track so that the door does not contact the track. A stabilizing roller may also be utilized so that the door and the track remain aligned as the door is traverse between the opened and closed positions.
More particularly, a door assembly with a door disposable in front of a door opening and traversable between an open position and closed position is disclosed. The door assembly may comprise the door, a bracket, a first magnet, a track, a second magnet and a stabilizing roller. The door may slide to the open and closed positions. The first door may define a length. The bracket may be attached to the first door. The first magnet may be attached to the bracket. The first magnet may have a length less than the length of the first door. The track may be disposed adjacent to the door opening. The track may define a length about two times a length of the first door. The bracket may be slidably mounted to the track. The second magnet may be attached to the track. The second magnet may have a length greater than a length of the door. The first and second magnets may be vertically aligned to each other. The stabilizing roller may be attached to the track and disposed within the track for vertically aligning the first and second magnets as the door is traversed between the open and closed positions.
The bracket may comprise first and second brackets disposed on either side of a vertical midline of the door.
The second magnet may be about greater than 80% of a length of the track.
The track may be embedded into a threshold of the structure surrounding the door opening. The track may be attached to left and right posts and/or header of the door which define the door opening.
The track may comprise a base and an insert having a cavity for receiving the second magnet. The insert may be inserted into a cavity defined by the base. The base may have a cavity in which a protrusion of the insert is freely insertable, and the protrusion of the insert may be held in place in the cavity of the base with an adhesive.
The first magnet may comprise a plurality of magnets disposed on opposed sides of the door so that the door is balanced on the second magnet.
The second magnet may be a single continuous magnet or a plurality of magnets positioned end to end to suspend the door evenly as the door is traversed between the open and closed positions.
A repelling force of the first and second magnets may be equal a weight of the door. It is also contemplated that the repelling force of the first and second magnets may be less than a weight of the door.
Another aspect of the present disclosure is a door assembly with a door disposable in front of a door opening and traversable between an open position and closed position. The door assembly may comprise the door. The door may be slidable to the open and closed positions. The door may define a length.
The door assembly may further comprise a bracket attached to the door. The door assembly may further comprise a first permanent magnet. The first permanent magnet may comprise a plurality of permanent magnets attached to the bracket. The first permanent magnet may define a length and a width. The first permanent magnet may have north and south poles. The first permanent magnet with may be horizontally transverse to the length of the door.
The door assembly may further comprise a guard attached to the bracket between each of the plurality of permanent magnets. The guard may extend out of the bracket at a direction horizontally transverse to the length of the door.
The door assembly may further comprise a track disposed adjacent to the door opening. The bracket may be slidably mounted to the track.
The door assembly may further comprise a second permanent magnet attached to the track. The second permanent magnet may have north and south poles. The like poles of the first and second permanent magnet may face each other to repulsively lift an entire weight of the door up. The second permanent magnet may have a width horizontally transverse to the length of the door. The second permanent magnet width may be different than the first permanent magnet width. The second permanent magnet may have a length greater than a length of the door. The first and second permanent magnets may be vertically aligned to each other.
The door assembly may further comprise at least one guide attached to the bracket along a direction of the length of the first permanent magnet to slidably mount the bracket to the track and maintain vertical alignment and engagement between the track and bracket as the door is traversed between the open and closed positions. The guard may limit lateral movement of the first permanent magnet relative to the second permanent magnet such that the entire weight of the door is lifted magnetically when the door moves laterally
The bracket may comprise first and second brackets disposed on either side of a vertical midline of the door.
The length of the second permanent magnet may be greater than 80% of the length of the track.
The second permanent magnet may be a plurality of permanent magnets. Each permanent magnet of the plurality of permanent magnets may have a length less than the length of the door. The plurality of permanent magnets may collectively have a length greater than the length of the door.
Some of the plurality of permanent magnets of the first permanent magnet may be disposed on opposed sides of the door so that the door is balanced on the second permanent magnet.
The second permanent magnet may be a single continuous permanent magnet or a plurality of permanent magnets positioned end to end to suspend the door evenly as the door is traversed between the open and closed positions.
The repelling force of the first and second permanent magnets may be equal to or less than a weight of the door.
The second permanent magnet may have a width greater or less than the first permanent magnet width.
The guard and the at least one mounting may each have curved surfaces directly and slidably contacting the track.
The door assembly may be a first door assembly. The door assembly may further comprise a second door assembly mirroring the first door assembly about a vertical plane. The door of the first door assembly and the door of the second door assembly may be slidable independent from each other.
The magnetic field of the first permanent magnet may be wider or narrower compared to a magnetic field of the second permanent magnet.
Another aspect of the present disclosure is a door assembly with a cover disposable in front of a door opening and traversable between an open position and closed position. The door assembly may comprise the cover. The cover may be slidable to the open and closed positions. The cover may define a length.
The door assembly may further comprise a bracket attached to the cover.
The door assembly may further comprise a first permanent magnet comprising a plurality of permanent magnets attached to the bracket. The first permanent magnet may define a path as the cover slides between the open and closed positions. The first permanent magnet may define a width horizontally transverse to the path of the moving first permanent.
The door assembly may further comprise a guard attached to the bracket between each of the plurality of permanent magnets. The guard may extend out of the bracket at a direction horizontally transverse to the path of the moving first permanent magnet.
The door assembly may further comprise a guard attached to the bracket between each of the plurality of permanent magnets. The guard may extend out of the bracket at a direction horizontally transverse to the path of the moving first permanent magnet.
The door assembly may further comprise a track disposed adjacent to the door opening. The bracket may be slidably mounted to the track.
The door assembly may further comprise a second permanent magnet attached to the track. The second permanent magnet may define a width horizontally transverse to the first permanent magnet path. The first and second magnets may be vertically aligned. The like poles of the first and second permanent magnets may face each other to repulsively lift the door. Strengths of the first and second permanent magnets may be sufficiently strong to repulsively lift and entire weight of the door.
The door assembly may further comprise at least one guide attached to the bracket along the path of the moving first permanent magnet to slidably mount the bracket to the track and maintain vertical alignment and engagement between the track and bracket as the cover is traversed between the open and closed positions.
The cover may be a door or a curtain.
The track may define a length and the length of the track may be greater than the length of the cover.
The magnetic field of the first permanent magnet may have a first range and the magnetic field of the second permanent magnet may have a second range, the first range being greater or smaller than the second range.
Another aspect of the current disclosure is a method of assembling a cover assembly with a cover disposable in front of a cover opening and traversable between an open position and a closed position. The method may comprise the step of providing the cover. The cover may be slidable to the open and closed positions after assembly of the cover assembly. The cover may define a length.
The method may further comprise the step of providing a bracket attachable to the cover.
The method may further comprise the step of providing a first permanent magnet comprising a plurality of permanent magnets attachable to the bracket. The first permanent magnet may define a path as the cover slides between the open and closed positions. The first permanent magnet may define a width transverse to the path of the moving first permanent magnet.
The method may further comprise the step of providing a guard attachable to the bracket between each of the plurality of permanent magnets.
The method may further comprise the step of providing a track disposable adjacent to the cover opening. The bracket may be slidably mountable to the track. The track may have a recess along a length of the track.
The method may further comprise the step of providing a second permanent magnet attachable to the track. The second permanent magnet may have a length greater than a length of the cover. The first and second permanent magnets may be vertically alignable to each other. The second permanent magnet may define a width transverse to the first permanent magnet path. The width of the second permanent magnet width may be different than the first permanent magnet width.
The method may further comprise the step of providing at least one guide attachable to the bracket.
The method may further comprise the step of attaching the first permanent magnet to the bracket.
The method may further comprise the step of attaching the guard to the bracket between each of the plurality of permanent magnets of the first permanent magnet.
The method may further comprise the step of disposing the track adjacent to the cover opening.
The method may further comprise the step of attaching the at least one guide to the bracket along the path of the moving first permanent magnet.
The method may further comprise the step of slidably mounting the bracket to the track. The track may be in direct contact with the guard and the at least one guide.
The method may further comprise the step of vertically aligning the first and second permanent magnets to each other with like poles of the first and second permanent magnets facing each other. The strengths of the first and second permanent magnets may be sufficiently strong to repulsively lift and entire weight of the door.
The method may further comprise disposing the first and second permanent magnets vertically above each other. The guard may limit lateral movement of the first permanent magnet relative to the second permanent magnet such that the door is repulsively lifted when the door moves laterally.
The second permanent magnet may be a plurality of permanent magnets. Each permanent magnet of the plurality of permanent magnets may have a length less than the length of the cover. The plurality of permanent magnets may collectively have a length greater than the length of the cover.
Some of the plurality of permanent magnets of the first permanent magnet may be disposed on opposed sides of the cover so that the cover is balanced on the second permanent magnet.
The second permanent magnet may be a single continuous permanent magnet or a plurality of permanent magnets positioned end to end to suspend the cover evenly as the cover is traversed between the open and closed positions.
The step of providing the first permanent magnet and the step of providing the second permanent magnet may include the step of providing the first permanent magnet with a magnetic field wider or narrower than a magnetic field of the second permanent magnet.
These and other features and advantages of the various embodiments disclosed herein will be better understood with respect to the following description and drawings, in which like numbers refer to like parts throughout, and in which:
Referring now to the drawings, a magnetically levitated shower glass door 10, 100, 200, 300, 400, 500, 600, 700, 800 is shown. The glass door 10, 100, 200, 300, 400, 500, 600, 700, 800 may be slid horizontally in the direction of arrow 12 on track 14, 114, 214, 314, 414, 514, 614, 714, 814. The glass door 10, 100, 200, 300, 400, 500, 600, 700, 800 may have a short magnet 16, 116, 216, 316, 416, 516, 616, 716, 816. The track 14, 114, 214, 314, 414, 514, 614, 714, 814 may have a long magnet 18, 118, 218, 318, 418, 518, 618, 718. The magnets 16, 116, 216, 316, 416, 516, 616, 716 may be repelled by the magnets 18, 118, 218, 218, 318, 418, 518, 618, 718 to vertically lift the glass door 10, 100, 200, 300, 400, 500, 600, 700 so that as the glass door 10, 100, 200, 300, 400, 500, 600, 700 moves horizontally in the direction of arrow 12, 112, 212, 312, 412, 512, 612, 712 and the weight of the glass door 10, 100, 200, 300, 400, 500, 600, 700 is transferred to the track 14, 114, 214, 314, 414, 514, 614, 714 through the short magnets 16, 116, 216, 316, 416, 516, 616, 716 and the long magnets 18, 118, 218, 318, 418, 518, 618, 718. A minimal amount of contact occurs between the track 14, 114, 214, 314, 414, 514, 614, 714 and the glass door 10, 100, 200, 300, 400, 500, 600, 700 so that the horizontal movement of the glass door 10, 100, 200, 300, 400, 500, 600, 700 is quiet and smooth.
Referring now to
The track 14 extends from the first wall 22 to the second wall 24 and is secured with a bracket 32 (see
The sliding door 10 may be attached to at least two brackets 42. The brackets 42 position the magnet 16 above the magnet 18 to lift the door 10 upward due to the repelling force of the magnets 16, 18. Two brackets 42 are needed and are attached to the door 10 on either side of a vertical midline 44 of the door 10 which bisects the length 38 or at a center of gravity of the door 10. Preferably, the brackets 42 are placed equidistantly away from the vertical midline 44 so that each of the brackets 42 and the magnets 16 support the door 10 evenly. In this regard, a distance 44 from the midline 44 to one of the brackets 42 is equal to the distance 46 from the midline 44 to the other one of the brackets 42.
The figures and the description refer to two brackets 42. However, it is also contemplated that the two brackets 42 may be replaced with one long bracket having either two magnets 16 on both sides of the vertical midline 44 of the door 10 or one long magnet 16 that extends to both sides of the vertical midline 44 of the door 10. Preferably, the magnet 16 extends as far to the opposed sides of the door 10 as possible to provide as much balance to the door 10 as it is slid left to right. Additionally, when two magnets 16 are used, it is preferable that the magnets 16 are disposed as far away from the vertical midline 44 or center of gravity as possible. Once again, this is to provide as much balance as possible to the door 10 as the door 10 is being slid left to right.
The magnets 16 of the sliding door 10 are repelled away from the magnet 18. The repelling force of the magnets 16 is sufficiently strong so that the bracket 42 does not physically contact a top of the track 14 but is vertically lifted up due to the magnetic repelling forces. Alternatively, the repelling force of the magnets 16 may be sufficiently weak so that the bracket 42 may physically contact the top of the track 14 but only a small portion of the weight of the glass door 10 is physically supported by contact of the bracket 42 on top of the track 14. That small portion may be between about 1% to 30% of the weight of the glass door 10, and is more preferably about between 1% to 10% of the weight of the glass door 10. Since there are two magnets 16, one magnet 16 for each of the brackets 42, each magnet 16 is sufficiently strong to support half of the weight of the glass door 10. As a further alternative, the repelling force of the magnets 16 may be sufficiently strong so that the bracket 42 may physically contact a bottom of the track 14 and apply about a 2 lbs. to 20 lbs. force. The prongs 66 may be replaced with rollers that ride within the grooves 68.
The repelling force of the magnet 16 to the magnet 18 may be adjusted by increasing or decreasing a length 48 (see
For example, if the sliding glass door 10 weighs about 50 pounds, then each pair of magnets 16, 18 would produce a repelling force of about 25 pounds. In this way, at least a majority of the weight if not all of the weight of the sliding door 10 is supported by the repelling forces of the magnets 16.
The door 10 may have at least two brackets 42. The bracket 42 may circumscribe the track 14. An internal width 58 may be greater than an external width 60 of the track 14. This allows the bracket 14 to be horizontally traversed left and right in the direction of arrow 12. Moreover, an internal height of the bracket 42 may be greater than an external height of the track 14. The bracket 42 may have at least two rollers 62 that allow the bracket 42 to roll on the track 14. More particularly, the rollers 62 may be aligned to grooves 64 formed along a length of the track 14. The rollers 62 may engage the grooves 64 when the repelling forces created by the magnets 16, 18 are not sufficient to fully lift the door 10. Nevertheless, an insignificant amount of weight may be supported by the rollers 62 because the magnets 16, 18 may be sized to provide repelling forces that carry 80%, and more preferably 95%, if not 100% of the weight of the door 10.
The bracket may have tongues 66 that are aligned to grooves 68 and support the bracket 42 when the door is not mounted to the bracket 42, and the repelling forces created by the magnets 16, 18 drive the bracket 42 upward, as shown in
The bracket 42 may be fabricated from a metallic material. The brackets 42 may be mounted (i.e., slid on) on the track 14 first, then the track 14 mounted to the first and second walls 22, 24. Thereafter, the glass door 10 may be mounted to the bracket 42. Alternatively, the bracket 42 may be fabricated from a plastic material and the bracket 42 slipped over the track 14 by bending the bracket 42 outward and over the track 14.
The door 10 may define a lower end portion 70 that fits within a guide 72 that extends along the entire sill 30 so that the door 10 remains vertically upright when it is slid left and right.
Referring now to
The tracks 114, 115 may extend from the first wall 22 to the second wall and may be secured with a bracket and fastener 132. Referring now to
The bracket 142 may have one magnet vertically aligned above a center of gravity of the door 100 or 101. Alternatively, as shown in
The tracks 114, 115 may have corresponding magnets 115, 119. These magnets 116, 115 and magnets 117, 119 produce repelling forces that carry about 80%, more preferably 95% to 100% of the weight of the door 100 or 101. Since there are two brackets 42 for each of the doors 100, 101 and there are two magnets 116, 115 and 117, 119 for each bracket 142, each magnet 116, 117 may be designed to carry about 25% of the weight of the door 100 or 101. By way of example and not limitation, the repelling forces may be adjusted by increasing or decreasing a width, height or length of the magnets 116, 115, 117, 119.
The tracks 114, 115 may have internal grooves 166 that receive rollers 162 when the door 100, 101 is mounted to the bracket 114, 115. A majority or all of the weight may be supported by the repelling forces created by the magnets 116, 115 and the magnets 117, 119. In
Referring now to
The brackets 142 are mounted equidistantly from a vertical midline 144 of the door 100 or 101.
Referring now to
The length 240 of the magnet 218 attached or embedded into the sill 230 may be about equal to twice the length 236 of the glass door 200 that slides back and forth. A length 238 of the magnet 216 disposed at the bottom portion of the glass door 200 may be about 80% to 100% of a length 236 of the glass door 200.
The bottom end of the door 200 may have rollers that roll on a bottom surface of the U-channel 288 so that if the repelling forces created by the magnets 216, 218 are not sufficient to lift the door fully upward, the rollers will support the door and allow the door to slide left to right. The rollers may be placed on both sides of the vertical midline 292 of the door 200 so that the rollers can evenly support the door 200 when it is being slid back and forth.
Additionally, the magnet 216 is shown and described as being a single elongate magnet that extends across more than 50% of a length 236 of the door 200. However, it is also contemplated that the magnet 216 may be a plurality of magnets that are distributed along the length 236 of the door 200 to evenly lift the door 200 upward. By way of example and not limitation, the magnet 216 may be two (2) separate magnets that are placed on both sides of the vertical midline 262 at the lower end portion of the door 200.
The repelling force may be adjusted by adjusting a length, width, height of the magnets 216, 218.
Referring now to the
The track 314 may extend from the first wall to the second wall and may be secured with a bracket and a fastener. The track 314 may have an elongate magnet 318 that may extend substantially along the length of the track 328 or fully along the entire length of the track 328 so that the magnets 316 are always repelled by the magnet 318 when the door 300 is in the opened position, the closed position or transitioned therebetween. In the example shown in
The sliding door 300 may be attached to at least two brackets 342 and a top member 374. The top member 374 is long enough to secure the brackets 342 to the top member 374. The brackets 342 may be attached to the sliding door 300 at the upper end portion of the sliding door 300. The top member 374 may be attached to the bracket 342 by way of a tongue and groove connection 376. In particular, the top member 374 may have a V-notch on the left and right sides thereof 374. The brackets 342 may have a housing 378 with matching V-configured tongues. The V-configured tongues may slide into the V-configured notch of the top member 374 and be held in place by an adhesive or a set screw. The housing 378 of the bracket 342 may be attached to a pair of plates that are secured to the glass door 300. The pair of plates 380 sandwich the door 300 and are secured to the housing 378 with a bolt 381.
The two brackets 342 may be attached to the door 300 on either side of the vertical midline 344 of the door 300. The brackets 342 may be spaced apart from the vertical midline 344 at an equal distance from the vertical midline 344 so that the repelling forces of the magnets 316, 318 may be evenly applied vertically up to hold the door 300 level and so the brackets 342 do not contact the track 314 or do so minimally. The magnet 316 may be embedded in the top member 374 within a cavity 382 that extends along the length of the top member 374. The magnet 316 may be a single elongate magnet that extends across at least 50% of the top member 374 up to the entire length of the top member 374. The magnet 316 may be positioned so that it is evenly distributed on the vertical midline 344 when assembled.
It is also contemplated that the magnet 316 may be a plurality of magnets 316. In this case, the plurality of magnets may be evenly distributed along the length of the top member 374 so that the repelling forces generated by the magnets 316, 318 apply even upward forces on brackets 342. This is to allow the magnets 316, 318 to hold the door 300 in a level position.
The track 314 may also have a cavity 383 that receives the magnet 318. Magnet 318 may extend across the entire length of the track 314 or a sufficient length of the track 314 so that the magnets 316 embedded in the top member 374 are always being repelled away by magnets 318. By way of example and not limitation, the magnet 318 may extend across 80% or 90% of the length of the track 314. The magnets 316, 318 may be embedded and held in place in cavities 382, 383 with an adhesive or other attachment mechanism such as a screw. The repelling forces generated by the magnets 316, 318 may be equal to the weight of the sliding door 300 including the bracket 342, top member 374 and the magnet 316 and other components that may be attached to the sliding door or move with the sliding door as the sliding door 300 traverses between the closed and opened position. The configuration of the magnets 316, 318 may be identical to the configuration of the magnets 16, 18 in relation to the embodiment shown in
Referring now to
Referring now to
The distribution of the magnets 416 may follow the same guidelines as that of the magnets 316 discussed in relation to the fourth embodiment of the shower door 320. Additionally, the magnet 418 may be embedded within the track 414 similar to the magnet 318 in relation to the track 314.
The track 414 may have a groove 476. The groove 476 may receive one or more wheels 478 that are attached to the sliding door 300. For example, as shown in the figures, the sliding door 300 may have two wheels 478 that are horizontally level with each other. The wheels 478 may ride within the groove 476 of the track 414.
The wheels 478 may be rotatable in direction of arrow 479 about a central axis. The wheels 478 may rotate as they 478 are traversed within the groove 476 of the track 414. Preferably, the wheel 478 does not touch the track 414 as the sliding door 400 is traversed between the opened and closed positions. Rather, the repelling force generated by the magnets 416, 418 should be counterbalanced by the weight of the door 400. More particularly, the repelling force of the magnets 416, 418 may be equal to a weight of the door. The wheels 478 preferably do not carry any weight of the door 400. However, the wheel or wheels 478 may have ridges 480 that are received into slots 481 formed in the groove 476. In this manner, the door 400 is not allowed to slide off of the track 414.
The weight of the door 482 is represented by arrow 482 and is offset 483 to the upward force 484 generated by the magnets 416, 418. The repelling force of the magnets 416, 418 is represented by arrow 484. This offset 483 will cause the door to rotate in the direction of arrow 485. In order to keep the door 400 in a vertical orientation, a roller 486 may be disposed on a medial side of the door 400 at the lower end portion of the door 400 and be positioned so as to maintain the door 400 in a vertical orientation. The roller 486 may rotate as the door pushes against the roller 486 and the door 400 is traversed between the opened and closed positions.
Referring now to
Referring now to
The track 614 may be a single elongate extruded piece of aluminum or other suitable material. Alternatively, the track 614 may be fabricated from multiple elongate extruded pieces of aluminum that are assembled together. By way of example and not limitation, the track 614 may have extruded inserts 678a, b. In this regard, the track 614 may include a base 680 and the two inserts 678a, b. The base 680 may have a cavity 682 that receives the magnet receiving member 674a, b. In particular, the base 680 may have cavities 682a, b that each individually receives the magnet receiving members 674a, b and the inserts 678a, b. The inserts 678a, b may be received into cavities 692a, b. The inserts 678a, b may have a base 694a, b. The base 694a, b may have a matching configuration compared to the cavities 692a, b. By way of example and not limitation, the base 694a, b and the cavities 692a, b may have matching trapezoidal configurations. The base 694a, b may freely slide into the cavities 692a, b. The base 694a, b may be held into place with an adhesive (e.g. silicone). The base 680 and the inserts 678a, b may be sufficiently long so that the opposing ends are attached to the walls 22, 24. In contrast, the magnet receiving members 674a, b may be sufficiently long to extend across a substantial part or the entire width of the door 600a, b. More particularly, the magnet receiving member may comprise bracket 642 which extends across the substantial part or the entire width of the door 600a, b.
Also, the magnet receiving members 674a, b may have stabilizing rollers 684a, b on opposed ends of the doors 600a, b, as shown in
The bottom side of the bracket 642a, b may have a bracket 679 which attaches the glass door 600a, b to the bracket 642a, b of the magnet receiving member 674a, b.
Referring now to
The track 714 and a magnet receiving member 774a, b which may be attached to the door 700a, b may have magnets 716a, b, 718a, b embedded therein that produces a repelling force to lift the door 700a, b and prevent any or minimal contact therebetween.
The magnet receiving member 774a, b may have stabilizing rollers 784a, b. The stabilizing rollers 784a, b may be disposed on opposing ends of the doors 700a, b as shown in
Moreover, the doors shown and described herein are described as being glass doors. However, it is also contemplated that the doors may be fabricated from other materials as well including but not limited to wood, plexiglass, and the like. In the various aspects and embodiments described above, the brackets were described as being equidistantly set apart from a vertical midline of the door. In this regard, the repelling forces generated by the magnets embedded in the brackets on opposed sides of the vertical midline are equal to each other. However, it is also contemplated that the repelling forces generated on opposed sides of the vertical midline may be located asymmetrically about the vertical midline and also generate asymmetrical repelling forces but yet evenly lift the door upward.
The track 14, 114, 314, 414, 514, 614, 714 may be directly or indirectly attached to the structure around the door opening so that the track 14, 114, 314, 414, 514, 614, 714 may be disposed above the door opening and the door that engages the track 14, 114, 314, 414, 514, 614, 714 may be traversed between an opened and closed position. In the closed position, the door is disposed in front of the door opening so that people and things cannot be passed through the door opening. In the opened position, the door is displaced away from the door opening so that people and things can pass through the door opening. It is also contemplated that the track 14, 114, 214, 314, 414, 514, 614 may be embedded within the structure around the door opening so that the track is less noticeable during use. The structure around the door opening may be the wall, header, threshold, floor. In this regard, the door may function as a barn door in front of a door opening.
In the seventh and eighth embodiment shown in
Referring now to figures herein, by way of example and not limitation, a magnetically levitating sliding door 810, 1010 is shown. The door 810, 1010 may slide horizontally in the direction of arrow 812, 1012 on track 814, 1014. The door 810, 1010 may have a magnet 816, 1016. The track 814, 1014 may have a magnet 818, 1018. The magnet 816, 1016 may be repelled by the magnet 818, 1018 to vertically lift the door 810, 1010 when the door 810, 1010 is assembled and hung on the track 814, 1014. In this way, as the door 810, 1010 moves horizontally in the direction of arrow 812, 1012, the weight of the door 810, 1010 is transferred to the track 814, 1014 through magnets 816, 1016 and 818, 1018. A minimal amount of contact or no contact occurs between the track 814, 1014 and the door 810, 1010 in terms of the vertical direction. When the door 810, 1010 is slid left and right in the direction of arrow 812, 1012 the horizontal movement of the door 810, 1010 is quiet and smooth because the bracket 842, 1042 and the track 814, 1014 preferably do not rub against each other.
Referring now to
As shown in
Referring now to
The sliding door 810 may be attached to bracket 842. The bracket 842 may position the magnet 816 above the magnet 818 attached to the track 814 to lift the door 810 upward due to the repelling force of the magnets 816, 818. The magnet 816 attached to the door 810 may be a single magnet or a plurality of magnets. Regardless of the number of magnets 816 that is provided in the bracket 842, the one or more magnets 816 may be evenly distributed about a midline 844 of the door that intersects a center of gravity of the door 810. The magnet 816 may be evenly distributed in that the magnet 816 provides an equal upward force on the left of the midline 844 compared to the right of the midline 844 so that the door 810 is raised evenly upward. The door 810 may appear horizontal or level to the ground. If the magnet 816 is provided as two separate or individual magnets, then magnet 818 may be provided as a singular elongate and contiguous magnet along a length 874 of the track 814 as needed to provide the repelling force as the door 810 slides left to right.
The converse may also be true. In particular, the magnet 818 may be provided as two or more magnets evenly distributed about a length of the track 814. If so, then the opposing magnet 816 may be provided as a single elongate and contiguous magnet that may have a length 48. The length 848 of the magnet 816 may be sufficiently long so that a repelling force is generated by two or more magnet immediately adjacent segments of magnet 818 so that the sliding motion of the door is not a stop and go motion as the magnet 816 transitions from one magnet segment 818 to a segment of another adjacent magnet 818. The length 48 of the magnet 816 may be equal to the length of the bracket 842 or shorter so long as it opposes magnet 818. The magnet 816 may be disposed about the midline 844 of the door 810 so as to provide an equal repelling force on the left side of the midline 844 compared to the right side of the midline 844. The door 810 itself may be attached to the bracket 842 by way of clamps 876. The clamps 876 may be clamped onto a body of the door 810. The clamp 876 may have a protrusion that fits within a slotted hole 878 of the bracket. To level the door 810, a nut may be adjusted so that the door 810 appears level to the ground.
The repelling force of the magnets 816, 818 may be adjusted by increasing or decreasing the strength of the magnets 816, 818. Preferably, the repelling force created by the magnets 816, 818 is equal to the weight of the door 810 and lifts the door 810 evenly upward and gaps 884, 886 still is positive so that the door 810 can be pushed upward or downward.
Referring now to
Moreover, the repelling force generated by the magnets 816, 818 cannot be laterally balanced through magnetic forces when the sliding door 810 is in motion or stationary. By way of example and not limitation, referring to
In order to account for the vertical motion of the door 810, when sliding the door 810, and also to restrain the magnets 816, 818 so that they are vertically aligned and do not laterally fall off of one another, the bracket 842 may be attached to a slide 890. The slide 890 may have an inner member 892, an outer member 894 and a ball bearing race 896. The inner member 892 may have a trapezoidal notch 898 which receives a trapezoidal protrusion 900 of the bracket 842. The trapezoidal protrusion 900 may be inserted into the notch 898 and retained there in to attach the inner member 892, and thus the slide 890 to the bracket 842. The inner member 892 may have side walls 912 that define an indentation or bearing race 914 in which the bearings 916 are disposed in.
Preferably, the inner and outer members 892, 894 are fabricated in a heavy-duty fashion by using stiff and strong material so as to hold a portion of the weight of the door 810 if not the full weight of the door 810. Because the door 810 is preferably fully supported by the repelling force generated by the magnet 818, the slide 890 does not need to accommodate or be able to withstand vertical forces equal to the full weight of the door 810 but only a fraction thereof. By way of example and not limitation, slide 890 may withstand vertical forces between one to 20 pounds whereas the door 810 may weigh up to 100 to 200 pounds. However, it is also contemplated that the slide 890 may withstand or be rated to withstand vertical forces up to the weight of the door 810.
The ball bearing race 896 may include a plurality of holes 918 that can receive the ball bearings 916. The holes 918 may be sufficiently large so that the ball bearings 916 may freely rotate when disposed within the holes 916, as shown in
The outer member 894 may also have side walls 920 and bearing races 922. The ball bearings 916 slide within the races 914 and 922 of the inner and outer members 892, 894. The slide 890 may be sized lengthwise in order to allow the door 810 to slide its full length as designed or needed. The outer member 894, and more particularly the side walls 920 of the outer member 894 may define interface surfaces 924 (see
Additionally, a width 930 of the outer member 894 defined by the interface surfaces 924 may be less than an inner width 932 defined by the interior surfaces 926. Preferably, the interface surfaces 924 are parallel to each other on the left and right sides as shown in FIG. 39. Moreover, the interior surfaces 926 are preferably parallel to each other, also as shown in
During operation, when the door 810 is stationary, the magnets 816, 818 are not bottomed out in that gap 884 is still present or exists. Moreover, the repelling force is generated by the magnets 816, 818 are not sufficiently great so that the top of the outer member 894 does not touch a top 134 of the interior cavity 928. Preferably, gap 886 still exists. When the door 810 is traversed left to right in direction of arrow 812, the inner member 892 slides within outer member 894. The ball bearings 916 are held in place with ball bearing race 896. Preferably, the outer member 894 is longer than the inner member 892. The outer member 894 has a length 839 preferably equal to about or 80% a length of 818 of the track 814. The inner member 892 and the bearing race member 896 may be attached to each so that they do not slide against each other. The ball bearings 916 are held within the races 914, 922 of the inner and outer members 892, 894 and are held spaced apart from each other by bearing race 896. The lower member 892 and the bearing race 896 slide within the outer member 894 on the ball bearings 916.
Referring now to
The bracket 1042 is shown as being elongate and substantially equal to a width 38 of door 1010. The bracket 1042 may be elongate and be positioned centrally with respect to the midline 1044. A set of bearings 1136a, b, c may be positioned on one side of the midline 1044 and another set of bearings 1136a, b, c may be positioned on the other side of the midline 1044 of the door 1010. The two sets of bearings 1136a, b, c may be placed equidistantly from the vertical midline 1044 or at different distances so long as the door 1010 is stabilized. It is also contemplated that two or more sets of bearings 1136a, b, c may be positioned on one side of the midline 1044 and two or more sets of bearings 1136a, b, c may be positioned on the other side of the midline 1044 of the door. If so, then the two or more sets of bearings 1136a, b, c may be positioned on both sides of the midline 1044 in a configuration to stabilize the door 1010.
It is also contemplated that one bracket may be positioned on the left side of the midline 1044 of the door 1010 while another bracket 1042 may be positioned on the right side of the midline 1044. The brackets 1042 may be spread apart equidistant from the midline 1044 equally stabilize the upper portion of the door 1010 laterally on the left and right sides. At least one set of bearings 1136a, b, c may be attached to each of the brackets 1042 on the left and the right of the midline 1044.
The bearings 1136a, b, c may have a ball bearing 1138. The ball bearing 1138 may be pushed outward with a spring disposed behind the ball bearing 1138 and in the housing 1140. The ball bearing 1138 may be spring loaded. The ball bearing 1138 can be depressed into a housing 1140 to prohibit binding of the ball bearing 1138 as it rolls on the interior surfaces 1126 and the top surface 1134. The ball bearing mechanism 1190 may replace the drawer slide 890 shown in
The track 814, 1014 may be attached to the opposed walls 22,24. However, it is also contemplated that the track 814, 1014 may be hung on a side wall near an upper portion of a door opening. The track 814, 1014 may have French cleats 942, 1142 (see
Referring now to
Other configurations of how the stabilizing prong is attached to the track 1210 and bracket 1212 are also contemplated. By way of example and not limitation, the stabilizing prong may be formed as a part of the track 1210, and the bracket 1212 may have a recess in which the stabilizing prong is disposed in. Another configuration contemplates the stabilizing prong as a dual prong that is split like a fork so that the forked dual prongs receives the track 1210. In other words, the track 1210 may be received between the forked dual prongs which is a part of the bracket 1212. The reverse configuration is also contemplated. In particular, the forked dual prongs may be a part of the track 1210 and the bracket 1212 is received between the forked dual prongs of the track 1210.
Another further alternative embodiment contemplates two prongs. In
Referring still to
The embodiment shown in
Alternate positions of the magnets 16, 20 in relation to the stabilizing prong 22 and the recess 1224 are contemplated. By way of example and not limitation, in
The glass door 1226 may be attached to the bracket 1212 with a clamp 1228. Two different embodiments of the clamp 1228 are shown in
Other ways of attaching the bracket 1212 to the door 1226 are also contemplated as shown in
Referring back to
Referring now to
Referring now to
When the door 1226 is slid between the open and closed positions, the door 1226 may tilt. In this case, the track 1210 and the door 1226 may bump up against each other. Preferably, the bracket 1212 does not bottom out on the track 1210. The reason is that the magnetic repelling force is sufficient to prevent this situation. Referring now to
To prevent the track 1210 and bracket 1212 from shifting laterally, the door assembly may utilize the stabilizing prong 1222. As shown in
Other configurations of the nubs 1260 are also contemplated. By way of example and not limitation, the nubs 1260 may be formed in the track 1210 instead of the bracket 1212 as previously discussed. The stabilizing prong 1222 helps to prevent side to side motion between the track 1210 and the bracket 1212.
When side to side shifting occurs, the repulsive forces of the magnets 1216, 1220 may still be sufficient to lift the door 1226 up. However, when the side to side shifting is too great, then the bracket 1212 may bottom out on the track 1210. To prevent the bracket 1212 from slipping off and bottoming out on the track 1210, the side to side movement of the bracket 1212 is limited with a stabilizing prong 1222, as explained in the continued discussion of
However, to shape the magnetic fields of the first and second magnets 1216, 1220, one or more of the shapes, sizes and strengths of the magnets 1216, 1220 may be different from each other. By way of example and not limitation, the width 1214 of the first magnet 1216 may be different from the width 1218 of the second magnet 1220.
Referring to
In
The magnets 1216, 1220 may effectively repel each other to levitate the door assembly as the wider magnet 1216 shifts laterally relative to the narrower magnet 1220 along the direction of the arrow 1246; however, as the lateral shift leads to greater displacement, the magnets 1216, 1220 may no longer repel each other with the force necessary to levitate the door assembly, causing the bracket 1212 to bottom out on the track 1210. Hence, the stabilizing prong 1222 may be used to limit lateral shifting of the magnet 1216, as explained previously in the discussion of
In
Referring now to
The stabilizing prong 1222 may have various configurations. As shown in
The magnets 1216, 1220 are sized so that the repelling force of the magnets 1216, 1220 are equal to or greater than the weight of the door. More particularly, the magnets 1216, 1220 are sized so that the bracket 1212 is positioned in the position shown in
The door 1226 may be assembled in the following manner. In particular, the magnet 1216 is disposed within the recess 1240 of the bracket 1212. The magnet 1220 is also disposed in the recess 1242 of the track 1210. The bracket 1212 is then placed in position on the track 1210. When the door 1226 is sold or the door 1226 is provided to the end user, the door 1226 may be disengaged from the bracket 1212. The user may attach the track 1210 to the wall(s). At this point, the bracket 1212 is in the position shown in
The door in the embodiments disclosed herein may have a weight equal to or between 1 lb. to 2500 lbs. However, the door may preferably have a weight equal to or between 5 lbs. and 1000 lbs. More preferably, the door may preferably have a weight equal to or between 5 lbs. and 150 lbs.
Referring now to
Referring now to
A length 1174 of the track 1114 may be sufficiently long so that the door 1100 can slide laterally in the direction of arrow 1112 as needed. By way of example and not limitation, the length 1174 of the track 1114 may be about equal to or slightly less than two times a length 1138 of the door 1100.
The track 1114 may have a magnet 1118 (see
Referring now to
The bracket 1142 may have a guard 1123 along the length 1175 (see
Referring now to
Still referring to
Referring now to
When the track 1114 is installed, it does not need to be perfectly straight to prevent minor misalignment between the magnets 1116, 1118. Hence, it is easier to install when the magnets 1116, 1118 have different widths. This helps to mitigate wearing out of the guard 1123 because allowing for lateral movement without increasing lateral forces to keep the magnets 1116, 1118 aligned means that the door 1226 may exert a small lateral load on the guard 1123. Generally, the guard 1123 may last many sliding cycles such that the bracket 1142 may slide functionally for more sliding cycles than other sliding shower door mechanisms on the market before requiring maintenance. A plurality of guards 1123 may be attached evenly with respect to each side of the midline 1144 (see
Referring now to
The repelling force of the magnets 1116, 1118 may be adjusted by increasing or decreasing the strength of the magnets 1116, 1118. The repelling force of the magnets 1116, 1118 may be further adjusted by increasing or decreasing the size of the magnets 1116, 1118. It is also contemplated that the shape of the magnetic fields 1271, 1273 (see
Preferably, the repelling force created by the magnets 1116, 1118 is equal to the weight of the door 1100 and lifts the door 1100 evenly upward. A gap 1184 (see
Referring now to
Referring now to
Referring now to
The various aspects and embodiments described herein are directed to a magnetic levitation door and illustrated by way of a shower door. However, the various aspects and embodiments of the magnetic levitation door may be incorporated into a sliding screen door, sliding patio door, horizontally sliding window or any other door or opening with a panel that that horizontally slides to open and close the opening. The door in any of the embodiments can be any type of material or configuration. By way of example and not limitation, the door can be fabricated from wood, metal, plastic, cloth, accordion panels. The door assembly in any of the embodiments can be attached or hung between two walls (e.g., see
The above description is given by way of example, and not limitation. Given the above disclosure, one skilled in the art could devise variations that are within the scope and spirit of the invention disclosed herein. Further, the various features of the embodiments disclosed herein can be used alone, or in varying combinations with each other and are not intended to be limited to the specific combination described herein. Thus, the scope of the claims is not to be limited by the illustrated embodiments.
This application is a continuation of U.S. application Ser. No. 16/803,907, filed on 2020 Feb. 27, which is a continuation-in-part of U.S. application Ser. No. 16/554,084, filed on 2019 Aug. 28, which claims the benefit of U.S. Provisional Application No. 62/846,131, filed on 2019 May 10, U.S. Provisional Application No. 62/861,196, filed on 2019 Jun. 13, U.S. Provisional Application No. 62/861,262, filed on 2019 Jun. 13, and U.S. Provisional Application No. 62/892,325, filed on 2019 Aug. 27, the entire contents of which are incorporated herein by reference.
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20210246698 A1 | Aug 2021 | US |
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62892325 | Aug 2019 | US | |
62861262 | Jun 2019 | US | |
62861196 | Jun 2019 | US | |
62846131 | May 2019 | US |
Number | Date | Country | |
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Parent | 16803907 | Feb 2020 | US |
Child | 17245125 | US |
Number | Date | Country | |
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Parent | 16554084 | Aug 2019 | US |
Child | 16803907 | US |